Method for DOA Estimation of Coprime Arrays Through Joint Auxiliary Arrays with Atomic Norm Minimization in the Presence of Gain-Phase Errors
Authors: 
Qiang Guo, Wenjie Zhao, Liangang Qi, Yani Wang, Kaliuzhnyi Mykola, Stepan DupliiAuthors Info & Claims
Pages 6637 - 6660
Abstract
Coprime arrays (CPA) are extensively applied to estimate the direction of arrival (DOA). Yet, the effectiveness of existing DOA estimation algorithms for coprime arrays is predicated on the precise calibration of the array. Gain-phase errors in the sensors, when present, are magnified by the co-array, greatly impacting the performance of DOA estimation algorithms. To address the issue, this paper proposes a joint DOA estimation algorithm combining auxiliary arrays with atomic norm minimization. Exploiting the sub-array decomposition feature of coprime array, gain-phase error estimation is accomplished with the addition of precisely calibrated auxiliary arrays. Besides, the estimated gain-phase errors are used to correct the covariance of the signals received by the array. By combining array interpolation, all virtual sensors are fully utilized, and the interpolated virtual received signals are reconstructed into a Toeplitz matrix. The covariance matrix of these signals is then refined using atomic norm minimization, preparing the data for the final DOA estimation performed by subspace algorithms. In addition, for comparative analysis, the Cramér–Rao bound has also been derived under the condition of gain-phase errors, providing a benchmark for the performance of the proposed algorithm.
References
[1]
Cao SH, Ye ZF, Xu DY, et al. A hadamard product based method for doa estimation and gain-phase error calibration IEEE Trans. Aerosp. Electron. Syst. 2013 49 2 1224-1233
[2]
Chen H, Lin HG, Liu W, Wang Q, Shen Q, and Wang G Augmented multi-subarray dilated nested array with enhanced degrees of freedom and reduced mutual coupling IEEE Trans. Signal Process. 2024 72 1387-1399
[3]
Chen P, Chen ZM, Cao ZX, and Wang XB A new atomic norm for DOA estimation with gain-phase errors IEEE Trans. Signal Process. 2020 68 4293-4306
[4]
Friedlander B A sensitivity analysis of the MUSIC algorithm IEEE Trans. Acoust. Speech Signal Process. 1990 38 10 1740-1751
[5]
Friedlander B On the sensitivity of covariance based direction finding to gain and phase perturbations ICASSP, IEEE Int. Conf. Acoust. Speech Signal Process. Proc. 1992 4 445-448
[6]
Fu MC, Zheng Z, Zhang K, and Wang WQ Coarray interpolation for direction finding and polarization estimation using coprime EMVS array via atomic norm minimization IEEE Trans. Veh. Technol. 2023 72 8 10162-10172
[7]
Guo YD, Hu XW, Feng WK, and Gong J Low-complexity 2D DOA estimation and self-calibration for uniform rectangle array with gain-phase error Remote Sens. 2022 14 13 3010
[8]
Hu B, Shen XY, Jiang M, and Zhao KH Off-grid DOA estimation based on compressed sensing on multipath environment Int. J. Antennas Propag. 2023 2023 9315869
[9]
Hu B, Wu XC, Zhang X, Yang Q, and Deng WB DOA estimation based on compressed sensing with gain/phase uncertainties IET Radar Sonar Navig. 2018 12 11 1346-1352
[10]
Kou JX, Li M, and Jiang CL Robust direction-of-arrival estimation for coprime array in the presence of miscalibrated sensors IEEE Access 2020 8 27152-27162
[11]
Kou JX, Li M, and Jiang CL A robust DOA estimator based on compressive sensing for coprime array in the presence of miscalibrated sensors Sensors (Switzerland) 2019 19 16 3538
[12]
Liao B and Liao GS Method for array gain and phase uncertainties calibration based on ISM and ESPRIT J. Syst. Eng. Electron. 2009 20 2 223-228
[13]
Liu CL and Vaidyanathan PP Super nested arrays: linear sparse arrays with reduced mutual coupling—part I: fundamentals IEEE Trans. Signal Process. 2016 64 15 3997-4012
[14]
Liu CL and Vaidyanathan PP Remarks on the spatial smoothing step in coarray MUSIC IEEE Signal Process. Lett. 2015 22 9 1438-1442
[15]
C.L. Liu, P. P. Vaidyanathan, P. Pal, Coprime coarray interpolation for DOA estimation via nuclear norm minimization, in Proceedings—IEEE International Symposium on Circuits and Systems, 2016-July, pp. 2639–2642 (2016)
[16]
Li YX and Chi YJ Off-the-grid line spectrum denoising and estimation with multiple measurement vectors IEEE Trans. Signal Process. 2016 64 5 1257-1269
[17]
Li F and Vaccaro RJ Sensitivity analysis of DOA estimation algorithms to sensor errors IEEE Trans. Aerosp. Electron. Syst. 1992 28 3 708-717
[18]
Liu C, Tang X, and Zhang Z A new gain-phase error pre-calibration method for uniform linear arrays Sensors 2023 23 5 2544
[19]
Liu AF, Liao GS, Zeng C, Yang ZW, and Xu Q An eigenstructure method for estimating doa and sensor gain-phase errors IEEE Trans. Signal Process. 2011 59 12 5944-5956
[20]
C. F. Mecklenbräuker, P. Gerstoft, E. Ollila, Y. Park. Robust and Sparse M-Estimation of DOA. arXiv. (2023)
[21]
P. Pal, P. P. Vaidyanathan, Coprime sampling and the music algorithm. 2011 Digital Signal Processing and Signal Processing Education Meeting, DSP/SPE 2011 - Proceedings, 289-294 (2011)
[22]
Pal P and Vaidyanathan PP Nested arrays: a novel approach to array processing with enhanced degrees of freedom IEEE Trans. Signal Process. 2010 58 8 4167-4181
[23]
Pierre J and Kaveh M Experimental performance of calibration and direction-finding algorithms Proc. ICASSP IEEE Int. Conf. Acoust. Speech Signal Process. 1991 2 1365-1368
[24]
Qin S, Zhang YD, and Amin MG Generalized coprime array configurations for direction-of-arrival estimation IEEE Trans. Signal Process. 2015 63 6 1377-1390
[25]
H. Qiao, P. Pal. Unified analysis of co-array interpolation for direction-of-arrival estimation. ICASSP, in IEEE International Conference on Acoustics, Speech and Signal Processing - Proceedings, pp. 3056–3060 (2017)
[26]
Stoica P and Nehorai A MUSIC, maximum likelihood, and Cramer-Rao bound: further results and comparisons IEEE Trans. Acoust. Speech Signal Process. 1990 38 12 2140-2150
[27]
Shi ZG, Zhou CW, Gu YJ, Goodman NA, and Qu F Source estimation using coprime array: a sparse reconstruction perspective IEEE Sens. J. 2017 17 3 755-765
[28]
Sun FG, Gao B, Chen LZ, and Lan P A low-complexity ESPRIT-based DOA estimation method for co-prime linear arrays Sensors (Switzerland) 2016 16 9 1367
[29]
Sun B DOA estimation method for coprime array under gain and phase error Syst. Eng. Electron. 2021 43 12 3488-3494 in chinese
[30]
Tan Z, Eldar YC, and Nehorai A Direction of arrival estimation using co-prime arrays: a super resolution viewpoint IEEE Trans. Signal Process. 2014 62 21 5565-5576
[31]
Vaidyanathan PP and Pal P Sparse sensing with co-pprime samplers and arrays IEEE Trans. Signal Process. 2011 59 2 573-586
[32]
Wang MZ and Nehorai A Coarrays, MUSIC, and the Cramér-Rao Bound IEEE Trans. Signal Process. 2017 65 4 933-946
[33]
Wang MZ, Zhang Z, and Nehorai A Performance analysis of coarray-based MUSIC in the presence of sensor location errors IEEE Trans. Signal Process. 2018 66 12 3074-3085
[34]
Yang YZ, Wang JH, Cui WJ, and Ba B Coherent direction of arrival estimation based on low-rank matrix recovery utilising Linf2/inf-norm with moving coprime arrays IET Radar Sonar Navig. 2023 17 11 1646-1653
[35]
Yadav SK and George NV Fast direction-of-arrival estimation via coarray interpolation based on truncated nuclear norm regularization IEEE Trans. Circuits Syst. II Express Briefs 2021 68 4 1522-1526
[36]
Yang Z, Li J, Stoica P, et al. Sparse Methods for Direction-of-Arrival Estimation. 2016
[37]
L.M. Zhao, H.Q. Liu, Y. Li, Y. Zhou, DOA estimation under sensor gain and phase uncertainties, in Proceedings of 2015 International Conference on Estimation, Detection and Information Fusion, ICEDIF 2015, pp. 209–213 (2015)
[38]
Zheng Z, Wang WQ, Kong YY, and Zhang YD MISC array: a new sparse array design achieving increased degrees of freedom and reduced mutual coupling effect IEEE Trans. Signal Process. 2019 67 7 1728-1741
[39]
Zheng Z, Huang YX, Wang WQ, and So HC Direction-of-arrival estimation of coherent signals via coprime array interpolation IEEE Signal Process. Lett. 2020 27 585-589
[40]
Zhou CW and Zhou JF Direction-of-arrival estimation with coarray ESPRIT for coprime array Sensors (Switzerland) 2017 17 8 1779
[41]
C.W. Zhou, Z.G. Shi, Y.J. Gu, N. A. Goodman, Doa estimation by covariance matrix sparse reconstruction of coprime array. ICASSP, in IEEE International Conference on Acoustics, Speech and Signal Processing - Proceedings, 2015-August, pp. 2369–2373 (2015)
[42]
Zhou CW, Gu YJ, Fan X, Shi ZG, Mao GQ, and Zhang YD Direction-of-arrival estimation for coprime array via virtual array interpolation IEEE Trans. Signal Process. 2018 66 22 5956-5971
[43]
Zhang X, Zheng Z, Wang WQ, and So HC DOA estimation of coherent sources using coprime array via atomic norm minimization IEEE Signal Process. Lett. 2022 29 1312-1316
Index Terms
- Method for DOA Estimation of Coprime Arrays Through Joint Auxiliary Arrays with Atomic Norm Minimization in the Presence of Gain-Phase Errors
Index terms have been assigned to the content through auto-classification.
Recommendations
A search-free DOA estimation algorithm for coprime arrays
Recently, coprime arrays have been in the focus of research because of their potential in exploiting redundancy in spanning large apertures with fewer elements than suggested by theory. A coprime array consists of two uniform linear subarrays with inter-...
L-shaped coprime array structures for DOA estimation
AbstractThis paper proposes a new sparse array geometry for 2-D (azimuth and elevation) direction-of-arrival (DOA) estimation based on coprime sampling. The proposed array structure is L-shaped coprime array (LCA) whose each portion is one dimensional ...
Coarray-domain iterative direction-of-arrival estimation with coprime arrays
AbstractIn this paper, we consider source direction-of-arrival (DOA) estimation with coprime arrays via coarray domain processing. We present two Fourier-based iterative methods which address the non-uniformity of the corresponding difference ...
Comments
Please enable JavaScript to view thecomments powered by Disqus.Information & Contributors
Information
Published In
© The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature 2024. Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.
Publisher
Birkhauser Boston Inc.
United States
Publication History
Published: 16 July 2024
Accepted: 23 May 2024
Revision received: 23 May 2024
Received: 15 December 2023
Author Tags
Qualifiers
- Research-article
Contributors
Other Metrics
Bibliometrics & Citations
Bibliometrics
Article Metrics
- 0Total Citations
- 0Total Downloads
- Downloads (Last 12 months)0
- Downloads (Last 6 weeks)0
Reflects downloads up to 17 Nov 2024
Other Metrics
Citations
View Options
View options
Login options
Check if you have access through your login credentials or your institution to get full access on this article.
Sign in